KR20060131112A - A dehumidifier - Google Patents

Abstract

A dehumidifier is provided to improve appearance and reduce noise by forming suction holes at lower ends of front and rear surfaces or side surfaces and discharging dehumidified air upward. A dehumidifier includes a main body case formed with inlets(112,122) at front and rear frames(110,120) or side surfaces for air suction, and an outlet(124) at a top surface. An adsorption assembly(200) is mounted in the case for absorbing moisture in the suction air. A suction assembly(300) is mounted at a side of the adsorption assembly for forcible suction of the air. A recycling assembly(400) is mounted at a side of the adsorption assembly for forcible circulation of the suction air.

Description

Dehumidifier {A dehumidifier}

1 is an exploded perspective view of a dehumidifier according to the prior art.

Figure 2 is a perspective view according to an embodiment of the dehumidifier according to the present invention.

3 is a perspective view according to another embodiment of the dehumidifier according to the present invention.

4 is an exploded perspective view of FIG. 2;

5 is an exploded perspective view of FIG. 3;

Figure 6 is a schematic air flow diagram of the dehumidifier according to the present invention.

Explanation of symbols on the main parts of the drawings

100. ..... Body Case 110. ..... Front Frame

112,122. ..... Inlet 112 ', 122'. ..... Suction Grill

120. ..... Rear frame 124. ..... Outlet

126. ..... discharge louver 127. ..... handle

128. ..... Handle groove 129. ..... Water tank entrance

130. ..... Filter 140. ..... Front Panel

150. ..... Display 160. ..... Control Box

170. ..... Heat Exchanger 180. ..... Regeneration Cover

200. ..... Adsorption assembly 220. ..... Adsorbent

240. ..... Suction rotor 260. ..... Suction rotor housing

262. ..... suction rotor cover 264. ..... rotor shaft

266. ..... Rotor Support Shaft 272. .....

274. ..... Circulating flow path 280. ..... Adsorption motor

282. ..... Rotor Gear 300. ..... Suction Assembly

320. ..... Suction fan 340. ..... Suction fan housing

342. ..... Rotating Shaft 344. ..... Rotating Shaft Support

350. ..... Suction Motor 360. ..... Motor Mount

380. ..... Discharge flow path 400. ..... assembly

420. ..... Play Fan 440. ..... Play Fan Housing

460. ..... regenerative motor 480. ..... heater

482. ..... Heater case 500. ..... Drain pan

520. ..... Drain groove 600. ..... Base fan

700. ..... Tank 720. ..... Tank cover coupling protrusion

740. ..... Water tank cover 742. ..... Water tank cover

744. ..... Tank handle 746. ..... Tank inlet

748. ..... Inlet cover 760. ..... Float

The present invention relates to a dehumidifier, and more particularly, to inhale indoor air into the front and rear or side lower end of the main body case and to be discharged to the upper side, less noise and dehumidifier is improved dehumidification efficiency.

Generally, a dehumidifier absorbs humid air in an indoor space into a case, passes a heat exchanger composed of a condenser and an evaporator through which a refrigerant flows, lowers humidity, and then discharges the dehumidified air back into the indoor space. It is a device to lower the humidity.

That is, the dehumidifier uses a method of taking heat from the surrounding air by evaporating the liquefied refrigerant in the evaporator. As the refrigerant evaporates, the temperature of the evaporator is lowered and the temperature of the air passing through the evaporator is also lowered.

Therefore, as the temperature around the evaporator decreases, moisture contained in the air condenses and condenses on the surface of the evaporator.

1 shows an exploded perspective view of a dehumidifier according to the prior art.

As shown in the drawing, the dehumidifier according to the prior art has a cabinet (1) equipped with a filter (4) on a rear surface of which a suction port is formed so that indoor air can be sucked, and the filter (4) mounted on the cabinet (1). A heat exchanger 20 positioned at the front of the heat exchanger 20 to perform dehumidification while exchanging heat with the indoor air, and a fan assembly 10 positioned at the front of the heat exchanger 20 to forcibly flow the indoor air and a lower portion of the heat exchanger It is formed in the water tank 30 to collect the condensate, and the front panel 3 and the like to form the front appearance, the discharge port 3a is formed.

However, the dehumidifier according to the prior art as described above has the following problems.

That is, in the dehumidifier according to the prior art, the discharge port 3a is formed in the front panel 3, so that the front appearance is not good, and it is difficult for the user to control the discharge direction.

In addition, the entrance and exit of the bucket 30 is formed on the rear of the cabinet 1 has a problem that the detachment of the bucket 30 is inconvenient.

In addition, even though the indoor air passing through the heat exchanger 20 is not completely dehumidified, the indoor air is directly discharged to the indoor space, thereby lowering the dehumidification efficiency.

Accordingly, an object of the present invention for solving the above problems is to provide a dehumidifier with good aesthetics, easy removal of the bucket and improved ease of use.

Another object of the present invention is to provide a dehumidifier in which the dehumidification efficiency is improved.

Dehumidifier according to the present invention for achieving the above object is a main body case forming an outer shape; A suction port formed in front and rear surfaces of the main body case to guide indoor air to be sucked into the main body case; An adsorption assembly provided inside the main body case to adsorb moisture contained in the air; A suction assembly provided at one side of the suction assembly to force indoor air to be sucked into the main body case; A recycling assembly provided at one side of the suction assembly and forcing the indoor air sucked into the main body case to circulate; It is formed on the upper surface of the main body case, characterized in that it comprises a discharge port for guiding so that the air sucked through the suction port is discharged upward.

And the dehumidifier according to the present invention comprises a main body case forming an outer shape; A suction port formed at a side of the main body case to guide indoor air to be sucked into the main body case; An adsorption assembly provided inside the main body case to adsorb moisture contained in the air; A suction assembly provided at one side of the suction assembly to force indoor air to be sucked into the main body case; A recycling assembly provided at one side of the suction assembly and forcing the indoor air sucked into the main body case to circulate; It is formed on the upper surface of the main body case, characterized in that it comprises a discharge port for guiding so that the air sucked through the suction port is discharged upward.

The main body case is characterized in that it comprises a front frame and a rear frame to form a front appearance to form a front appearance.

The suction port is formed on the lower end of the front frame and the rear frame.

The adsorption assembly includes an adsorbent for adsorbing moisture in the air, an adsorption rotor that receives and rotates the adsorbent, an adsorption rotor housing for supporting the adsorption rotor to rotate, and an adsorption motor for providing rotational power for the adsorption rotor to rotate. Characterized in that comprises a.

The suction assembly includes a suction fan that rotates to suck the indoor air into the suction port, a suction fan housing that receives and supports the suction fan, and a suction motor that provides rotational power to rotate the suction fan. It features.

The regeneration assembly may include a regeneration fan rotating to circulate air adsorbed by the adsorption assembly in the main body case, a regeneration fan housing accommodating and supporting the regeneration fan, and rotating power to rotate the regeneration fan. It characterized in that it comprises a regenerative motor to provide, and a heater for providing heat to dry the adsorbent of the adsorption assembly.

One side of the front frame and the rear frame is characterized in that it is provided with a filter for purifying the indoor air.

The front of the front frame is characterized in that the front panel further provides a beautiful front appearance.

According to the present invention having such a configuration, there is an advantage that the appearance is beautiful, the noise is small, and the dehumidification efficiency is improved.

Hereinafter, a preferred embodiment of a dehumidifier according to the present invention will be described in detail with reference to the accompanying drawings.

Figure 2 is a perspective view according to an embodiment of the dehumidifier according to the present invention, Figure 3 is a perspective view according to another embodiment of the dehumidifier according to the present invention, Figure 4 is an exploded perspective view of FIG. It is.

5 is an exploded perspective view of FIG. 3, and FIG. 6 is a schematic air flow diagram of the dehumidifier according to the present invention.

As shown in these drawings, the dehumidifier according to the present invention includes a main body case 100 which forms an outer shape, an adsorption assembly 200 which is provided inside the main body case 100 and adsorbs moisture contained in the air; The suction assembly 300 forcing the indoor air to be sucked into the main body case 100 and the regeneration assembly 400 for forcing the indoor air sucked into the main body case 100 to circulate.

The main body case 100 is formed in a substantially rectangular tubular shape, and divided into a first half and a second half, and are separately configured. That is, the main body case 100 is composed of a front frame 110 to form a front, side, and top appearance around a half of a rectangular cylindrical shape, and a rear frame 120 to form a rear, side, and top appearance. . Therefore, the front frame 110 and the rear frame 120 are formed in a rectangular cylinder with the rear and the front open respectively.

Suction ports 112 and 122 are formed on front and rear surfaces or side surfaces of the main body case 100 including the front frame 110 and the rear frame 120 to guide indoor air to be sucked. More specifically, the front frame 110 and the rear frame 120 is formed at the lower end, the shape of the inlet 112, 122 is shown in Figures 2 to 5.

First, the suction ports 112 and 122 are formed at the lower front and rear surfaces of the main body case 100 with reference to FIGS. 2 and 3. As shown in the figure, a predetermined open space is formed at the front lower end of the front frame 110 and the rear frame 120. The space formed to guide the indoor air to be sucked into the main body case 100 is formed. It will be the suction ports 112 and 122.

The suction ports 112 and 122 are formed in a substantially rectangular shape, and the suction ports 112 and 122 are provided with a filter 130 for purifying indoor air. The filter 130 serves to filter foreign matter in the air, a pre-filter for removing a relatively large dust contained in the air sucked into the suction ports 112 and 122, a deodorizing filter for removing odor, and dust by electric action. It can be configured as a single body composed of any one of the dust collecting filter and the hepa filter to remove the fine dust to collect the combination or an assembly consisting of a combination thereof.

The front panel 140 is installed in front of the front frame 110, the suction port 112 is formed to make the front appearance beautiful. The front panel 140 is formed in a square plate shape having the same size as the front size of the front frame 110, is coupled to the side of the front frame 110 is installed to be rotated laterally.

In addition, a suction grill 142 having a size corresponding to the suction port 112 of the front frame 110 is further formed at the lower end of the front panel 140.

On the upper surface of the front frame 110, a display unit 150 for displaying a state of operating the dehumidifier is formed transparently, a plurality of operation buttons for the operation of the dehumidifier is formed on one side of the display unit 150, although not shown do.

A control box 160 is provided below the upper surface of the front frame 110 in which the display unit 150 is formed to control the dehumidifier by operating the operation button. Although not shown inside the control box 160, a plurality of components such as a circuit board for controlling the operation of the dehumidifier as a whole are installed.

The lower portion of the control box 160 is provided with a heat exchanger 170 for performing a heat exchange action with the indoor air sucked into the suction port 112. The heat exchanger 170 is provided with two different in size and installed in a stack, and the air circulated by the regeneration assembly 400 to be described below is introduced into contact with the indoor air sucked into the inlet 112. In order to cause a lot of heat exchange, the inner passage is composed of a plurality of pipes connected to each other.

The rear of the heat exchanger 170 is provided with a regeneration cover 180 corresponding to the heater case 482 to be described below. The regeneration cover 180 serves to form a flow path such that the indoor air circulated by the regeneration assembly 400 to be described below is guided to the heat exchanger 170 again.

The rear of the regeneration cover 180 is provided with an adsorption assembly 200 for adsorbing moisture contained in the indoor air sucked into the suction port 112. The adsorption assembly 200 includes an adsorbent 220 that adsorbs moisture in air, an adsorption rotor 240 that receives and rotates the adsorbent 220, and an adsorption rotor housing that supports the adsorption rotor 240 to rotate. 260, and the suction motor 280 to provide a rotational power to rotate the suction rotor 240, and the like.

The adsorbent 220 is formed of a paper material and is formed in a circular shape, the inside is made of a honeycomb form a plurality of through holes are formed. More specifically, the two-ply paper is rolled in a honey-com form to be bonded to form a plurality of through holes, and the adsorbent 220 is made by impregnating a solution of the adsorption component on the bonded paper.

Therefore, when the indoor air passes through the through hole of the adsorbent 220, the air contained in the indoor air is adsorbed to the adsorbent 220 to dry the air.

The adsorbent 220 is formed in a circular shape and is mounted to the rotating adsorption rotor 240. The adsorption rotor 240 is made of a circular frame, the outer peripheral surface is formed in the shape of a cog wheel. The outer side of the suction rotor 240 is provided with a rotor gear 282 which is formed integrally with the suction motor 280 to rotate, the outer peripheral surface of the rotor gear 282 also corresponds to the outer peripheral surface of the suction rotor 240 It is formed into a gear shape.

Therefore, the rotor gear 282 is coupled to the adsorption rotor 240 to rotate slowly (eg, one revolution per minute) by the rotational power of the adsorption motor 280 to adsorb moisture in the air.

The suction rotor 240 is accommodated in and supported by the suction rotor housing 260. The adsorption rotor housing 260 is formed in a substantially rectangular plate shape, and the adsorption rotor cover 262 is formed in which a circular edge protrudes so as to penetrate the center portion thereof to accommodate the adsorption rotor 240.

In addition, a rotor rotation shaft 264 that is a rotation center of the suction rotor 240 is formed at a central portion of the suction rotor cover 262, and the rotor rotation shaft 264 is a central portion at an end of the suction rotor cover 262. It is supported and fixed by being coupled with the rotor shaft support 266 formed in plurality toward the.

In addition, the upper right portion of the adsorption rotor housing 260 to guide the air circulated in the heat exchanger 170 to the regeneration fan 420 to be described below corresponding to the regeneration flow path 272 to be described below. A circulation passage 274 is formed, and an adsorption motor 280 that provides rotational power to rotate the adsorption rotor 240 is integrally coupled to the rotor gear 282 at a lower end thereof.

The heater 480 is provided at the rear of the adsorption assembly 200 to provide heat to dry the adsorbent 220 as one component of the regeneration assembly 400 to be described below. The heater 480 is formed in a substantially fan shape and is accommodated and installed in the heater case 482 penetrating front and rear.

Accordingly, the heater case 482 is provided between the rotor rotation shaft support 266 is installed in the fan-shaped regeneration flow path 272 formed on the upper end of the suction rotor cover 262, a part of the adsorbent 220. It serves as a regeneration which continues to dry.

The suction assembly 300 is provided at the rear of the heater 480 to force the indoor air to be sucked into the suction port 112. The suction assembly 300 includes a suction fan 320 which rotates so that indoor air is sucked into the suction port 112, a suction fan housing 340 which accommodates and supports the suction fan 320, and the suction fan ( It consists of a suction motor 350 and the like to provide a rotational power to rotate 320.

The suction fan housing 340 is formed in a substantially rectangular plate shape, and a central portion thereof penetrates in a circular shape to constitute a flow path of indoor air sucked by the rotational force of the suction fan 320. A discharge passage 380 is formed at an upper end of the suction fan housing 340 to discharge the indoor air sucked by the suction fan 320 to the outside.

A rotating shaft support 344 is formed inside the suction fan housing 340 through which the suction fan 320 is easily rotated so as to accommodate the rotation shaft 342. The suction motor 350 that provides rotational power to rotate the suction fan 320 is mounted to the motor mount 360 is coupled to the rotation shaft support 344 is fixed.

A regeneration assembly 400 for forcing a portion of the indoor air sucked into the suction port 112 to circulate inside the main body case 100 is provided at the upper front of the suction assembly 300.

The regeneration assembly 400 is a regeneration fan 420 that rotates so that the indoor air sucked into the suction port 112 is circulated in the main body case 100, and a regeneration fan housing that accommodates and supports the regeneration fan 420. 440, and a regeneration motor 460 for providing a rotational power to rotate the regeneration fan 420, and the heater 480 for providing heat to dry the adsorbent 220.

The regeneration fan housing 440 is formed in a circular shape so that the regeneration fan 420 is mounted therein, and the air forcedly blown by the rotational force of the regeneration fan 420 is disposed on the upper end of the adsorption rotor cover 262. It is formed to a size corresponding to the fan-shaped regeneration flow path 272 is formed.

That is, the regeneration fan housing 440 guides the air blown from the regeneration fan 420 to the heater 480 and the regeneration flow path 272 to continuously dry a portion of the adsorbent 220 that rotates correspondingly. The regeneration is configured to continuously adsorb moisture contained in the indoor air sucked into the inlet 112 with the remaining adsorbent 220 except for the adsorbent 220 in the portion corresponding to the regeneration flow passage 272. It is preferable to form the size corresponding to the flow path (272).

Therefore, the moisture contained in the indoor air sucked by the suction fan 320 is adsorbed by the adsorbent 220 to be discharged to the outside through the discharge port 124, the portion corresponding to the regeneration flow path 272 The adsorbent 220 of the air is continuously dried by the high-temperature air converted by the air blown from the regeneration fan 420 passing through the heater 480, the high temperature and humid air passed through the adsorbent 220 The heat exchanger 170 is introduced into contact with indoor air to condense moisture in the air.

On the other hand, a drain pan 500 is installed below the heat exchanger 170 to collect the water condensed in the heat exchanger 170 and guide it to the water tank 700 to be described below. The drain pan 500 is formed in a substantially rectangular plate shape, and the drain groove 520 for guiding the water condensed in the heat exchanger 170 to the water tank 700 protrudes upward on the left side of the upper surface and is formed long before and after.

A base on which the heat exchanger 170, the suction assembly 200, the suction assembly 300, and the like are supported below the drain pan 500, and the front frame 110 and the rear frame 120 are installed at both ends. The fan 600 is provided. The base fan 600 is formed in a rectangular cylinder having an upper side and an open front side, and a water tank 700 for storing moisture generated from the heat exchanger 170 is provided to be slid out and pulled forward.

The water tank 700 is formed in a rectangular cylindrical shape of approximately the upper opening, the upper opening is provided with a water tank cover 740 to cover the upper surface of the water tank 700, both sides of the water tank cover will be described below A plurality of tank cover coupling protrusions 720 corresponding to the coupler 742 is formed to protrude.

A water tank handle 744 is formed at the center of the upper surface of the water tank cover 740 to facilitate the movement of the water tank 700, and is connected to the bottom surface of the drain groove 520 on the left side of the water tank handle 744. A water tank inlet 746 is formed to guide water to flow into the water tank 700.

In addition, an upper surface of the water tank inlet 746 is provided with an inlet cover 748 for preventing the water of the water tank 700 from flowing out when the water tank 700 enters and exits, and both sides of the water tank cover 740. At the end, two tank cover coupling holes 742 coupled to the tank cover coupling protrusion 720 are formed.

In addition, the inside of the water tank 700 is provided with a float (Float, 760) for detecting the full water level is moved in the vertical direction according to the water level when the water level is collected and the water level is changed. Although not shown, the float 760 is connected to a sensor and the like so that when the water in the tank 700 becomes full, the float 760 can be displayed to be recognized from the outside.

On the other hand, the rear of the suction assembly 300 is provided with a rear frame 120 to form a rear appearance of the dehumidifier. The rear frame 120 is formed in a size corresponding to the front frame 110 is coupled to the front frame 110 in the base fan 600 to form the body case 100.

An inlet 122 having the same function as the inlet 112 of the front frame 110 is formed at the lower end of the rear frame 120, and the front frame (front) of the inlet 122 of the rear frame 120 is formed. The filter 130 mounted on the 110 is further provided.

In addition, a discharge port 124 is formed on the upper surface of the rear frame 120 to be sucked through the suction ports 112 and 122 to flow into the main body case 100 to guide the dehumidified air to be discharged back into the indoor space. .

A discharge louver 126 is provided below the discharge port 124 to control the direction of the air discharged to the discharge port 124. Although not shown, the discharge louver 126 is installed to be slidable upward and downward from the discharge port 124 by flow means.

Therefore, when the dehumidifier is not operated, the discharge louver 126 is slid into the discharge port 124 (downward) to shield the discharge port 124. When the dehumidifier is operated, the discharge louver 126 is upward. The discharge port 124 is slid to open to adjust the direction of the dehumidified air discharged to the discharge port 124.

The upper surface of the rear frame 120, that is, the front of the discharge port 124 is formed with a handle 127 to easily move the dehumidifier. The handle 127 is hinged to the upper surface of the rear frame 120 is installed on both sides of the handle so as to be moved upward and downward, the handle 127 is seated when the handle 127 is flowed downward A handle groove 128 is formed.

In addition, a water tank entrance 129 through which the water tank 700 is retractably penetrated is formed at a lower side surface of the rear frame 120 and a lower surface side of the front frame 110.

Next, referring to FIGS. 4 and 5, the inlets 112 and 122 are formed on the lower side surfaces of the main body case 100. As shown in the figure, a predetermined open space is formed at the lower ends of both sides of the front frame 110 and the rear frame 120. The space formed in this way guides indoor air to be sucked into the main body case 100. It will be the suction ports 112 and 122.

Suction grills 112 'and 122' for guiding indoor air to the suction ports 112 and 122 are formed in the front frame 110 and the rear frame 120 in which the suction ports 112 and 122 are formed, and the suction grill 112 'is formed. A filter 130 for purifying indoor air is provided inside the 122 ', and a water tank entrance 129 through which the water tank 700 is drawn in and out is formed at the front lower end of the front frame 110.

In addition, the plurality of components provided in the main body case 100 are disposed in the same manner as the dehumidifier in which the inlets 112 and 122 are formed on the front and rear surfaces described above.

Hereinafter will be described the operation of the dehumidifier according to the present invention having the configuration as described above.

When the operation button (not shown) provided on the upper surface of the front frame 110 is manipulated by a user's arbitrary selection, the discharge louver 126 is provided at the discharge port 124 formed on the upper surface of the rear frame 120. ) Is exposed, the suction fan 320 of the suction assembly 300 is rotated.

In this case, the wet indoor air is sucked into the main body case 100 through the suction ports 112 and 122 formed on the front and rear surfaces or both sides of the front frame 110 and the rear frame 120 and is provided inside the main body case 100. Dehumidified air is discharged back to the interior space through the discharge port 124 by removing moisture contained in the air while passing through the heat exchanger 170, the adsorption assembly 200, and the suction assembly 300.

Here, the air flow inside the main body case 100 will be described in detail with reference to FIG. 6.

First, as indicated by a large arrow, when the humid air of the indoor space is sucked into the main body case 100 through the suction ports 112 and 122 by the rotational force of the suction fan 320, foreign matter in the air while passing through the filter 130. This is removed and passes through the adsorption assembly 200 via the heat exchanger 170.

The humid indoor air passing through the adsorption assembly 200 is dehumidified by adsorbing moisture in the air while passing through the through hole of the adsorbent 220, and the dehumidified air passes through the suction assembly 300 to the suction fan ( It is discharged to the interior space through the discharge port 124 by the rotational force of 320.

Next, the regeneration process of continuously drying the adsorbent 220 of the adsorption assembly 200 as indicated by the small arrow, the air forcedly blown by the rotation of the regeneration fan 420 is the regeneration fan housing 440 Passing through the heater 500, and passes through the heater 500 is converted to warm air to evaporate the moisture adsorbed to the adsorbent 220 to rotate.

In addition, the high temperature and high humidity air passing through the adsorbent 220 is moved to the heat exchanger 170 to circulate the inside of the heat exchanger 170, thereby causing heat exchange with indoor air sucked into the suction ports 112 and 122. Is condensed.

The water condensed in the heat exchanger 170 is guided to the drain pan 500 and stored in the water tank 700, and the air passing through the heat exchanger 170 is regenerated by the regeneration fan 420. The internal circulation guided to the regeneration flow path 272 via the circulation flow path 274 of the adsorption rotor housing 260 is repeated to continuously repeat the regeneration process of drying the adsorbent 220.

The scope of the present invention is not limited to the above-exemplified embodiments, and many other modifications based on the present invention may be made by those skilled in the art within the above technical scope.

As described in detail above, in the dehumidifier according to the present invention, the indoor air is sucked into the front and rear surfaces or the lower end of the main body case, and is configured to discharge upward. Therefore, the appearance of the dehumidifier is beautiful and there is no distinction between the front part and the rear part, so that the user can easily use it.

In addition, since the adsorption assembly for adsorbing moisture contained in the indoor air and the regeneration assembly for continuously drying the adsorbent are provided inside the main body case, the dehumidification efficiency is expected to be significantly improved compared to the conventional dehumidifier.

In addition, by removing the compressor provided in the conventional dehumidifier, the weight of the dehumidifier is reduced and the noise is less generated, so that the user's ease of use is also expected to be improved.

As a result, the design of the dehumidifier is beautiful, the weight and noise are reduced, and the effect of improving the dehumidification efficiency is expected to increase the purchase degree of the dehumidifier of the consumer.

Claims (9)

A main body case forming an outer shape; A suction port formed in front and rear surfaces of the main body case to guide indoor air to be sucked into the main body case; An adsorption assembly provided inside the main body case to adsorb moisture contained in the air; A suction assembly provided at one side of the suction assembly to force indoor air to be sucked into the main body case; A recycling assembly provided at one side of the suction assembly and forcing the indoor air sucked into the main body case to circulate; The dehumidifier is formed on the upper surface of the main body case, and comprises a discharge port for guiding the air sucked through the suction port to be discharged upward. A main body case forming an outer shape; A suction port formed at a side of the main body case to guide indoor air to be sucked into the main body case; An adsorption assembly provided inside the main body case to adsorb moisture contained in the air; A suction assembly provided at one side of the suction assembly and forcing indoor air to be sucked into the main body case; A recycling assembly provided at one side of the suction assembly and circulating the indoor air sucked into the main body case; The dehumidifier is formed on the upper surface of the main body case, and comprises a discharge port for guiding the air sucked through the suction port to be discharged upward. The main body case of claim 1 or 2, A front frame forming a front appearance, Dehumidifier comprising a rear frame to form a rear appearance. The dehumidifier of claim 3, wherein the suction port is formed at lower ends of the front frame and the rear frame. The method of claim 1 or 2, wherein the adsorption assembly, An adsorbent that adsorbs moisture in the air, A adsorption rotor rotating to accommodate the adsorbent; An adsorption rotor housing for supporting the adsorption rotor to rotate, Dehumidifier comprising a adsorption motor for providing a rotational power to rotate the adsorption rotor. The method of claim 1 or 2, wherein the suction assembly, A suction fan which rotates to suck the indoor air to the suction port, A suction fan housing accommodating and supporting the suction fan; Dehumidifier characterized in that it comprises a suction motor for providing a rotational power to rotate the suction fan. The method of claim 1 or 2, wherein the reproduction assembly, A regeneration fan rotating to circulate the air adsorbed by the adsorption assembly in the main body case; Regeneration fan housing for receiving and supporting the regeneration fan, A regeneration motor providing rotational power to rotate the regeneration fan; And a heater for providing heat to dry the adsorbent of the adsorption assembly. The dehumidifier of claim 3, wherein a filter for purifying indoor air is provided at one side of the front frame and the rear frame. The dehumidifier according to claim 3, further comprising a front panel which makes the front appearance beautiful in front of the front frame.

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